Evaluating Nurses’ Self-Efficacy related to In Situ Mock Code
Simulation Training1 IN SITU MOCK CODE SIMULATION
Evaluating Nurses’ Self-Efficacy related to In Situ Mock Code
Simulation Training
By Nicole Wedzina, ANP
A DNP project submitted to the School of Nursing
State University of New York in partial fulfillment of the
requirements for the degree of Doctor of Nursing Practice
February 2021
DNP Project Approval Form
(Name of Student)
Evaluating Nurses' Self-Efficacy related to In Situ Mock Code
Simulation Training
on January 11 (Date
Nancy Campbell, PhD, FNP, NP-C, CARN-AP, FAANP, FIAAN, FAAN DNP
Project Advisor (Required) (Typed Name)
~~ ~uu nature)
(Signature)
(Signature)
(Signature)
Acknowledgements
I cannot express enough thanks to my project committee, especially
Dr. Nancy Campbell
my project advisor, for her continued support and encouragement
when I was coming down to
the wire. I offer my sincere appreciation for her expertise that
she provided.
My completion of this project could not have been possible without
the support of the
Mock Code QI committee at my work facility, especially Shannon and
Matt. Hopefully, our
mock code program vision will become a reality soon.
Finally, to my patient and understanding husband, Jeret: my deepest
gratitude. Your
support and encouragement through all my endeavors are appreciated
and duly noted. It is a great
comfort that you are always there for me, especially when I need it
the most. And to my boys,
Sean and Joey, thank you for all your understanding and tolerant.
My heartfelt thanks.
“I find that the harder I work, the more luck I seem to have.”
-Thomas Jefferson
4 IN SITU MOCK CODE SIMULATION
Table of Contents
DNP Essentials………………………………………………….…...…………………….……...9
Theoretical Framework………………………………………………………………………….10
Abstract
Background and Significance: Hospital nurses need skills and
confidence to take action during
codes. In situ mock codes (ISMCs) can improve nursing confidence
during emergency situations.
Purpose, Aims, and Objectives: This study’s purpose was to identify
knowledge gaps in ISMC
training to enhance future ISMC education and improve nurses’
self-efficacy during code
situations.
Theoretical Framework: Albert Bandura’s Self-Efficacy Theory
emphasizes need for effective
learning to promote improved self-efficacy perceptions of task
performance.
Methods and Design: This study was a secondary data analysis from
survey results of 311
nurses using the Mock Code Self-Efficacy Survey (MCSES), a
validated measurement tool.
Descriptive and inferential statistics were used to describe nurse
self-efficacy of 12 code skills.
Differences in self-efficacy between medical-surgical (MS) and
critical care (CC) nurses were
examined and weak clinical areas identified.
Results: CC nurses had increased confidence in 11 of 12 clinical
skills when compared to MS
nurses. The only skill with no difference in confidence was
recognizing asystole. Nurses with
past mock code experience (PMCE) had more confidence in all 12
clinical skills than those
without. In all comparisons, dysrhythmia identification requiring
defibrillation and identifying
the first code medication administered were the weakest.
Conclusion: Overall, CC nurses and nurses with PMCE had higher
confidence levels in
performing the 12 clinical skills.
Future Implications: Lower confidence levels were discovered in MS
nurses and nurses with
less PMCE. Performing ISMCs routinely on MS units can increase
nurses’ experience and
confidence in code situations.
Keywords: in-situ mock codes, nurses’ self-efficacy in code
situations, mock code training
6 IN SITU MOCK CODE SIMULATION
Over 200,000 in-hospital cardiopulmonary arrests (IHCAs) occur each
year in the United
States (Josey et al., 2018). As first responders, hospital nurses
must have the skills and
confidence to promptly take action during a code situation.
Patients who have a cardiac arrest in
the hospital have a survival rate of approximately 10% to 23.9%
(Herbers & Heaser, 2016).
Positive outcomes for the patients during a medical emergency are
dependent on the abilities of
the nurses and code team to deliver the care needed quickly and
precisely during the critical first
few minutes of a cardiac arrest (Herbers & Heaser, 2016).
Prompt initiation of cardiopulmonary
resuscitation (CPR) and defibrillation are crucial for promoting
survival, as every minute of
postponed treatment decreases survival by 10% (Nallamothu et al.,
2018). Many nursing skills,
such as CPR, require evolving practice to ensure individuals can
perform efficiently and
competently (Mcphee, 2018). In the American Heart Association (AHA)
2013 Consensus
Statement, a recognized gap was noted that IHCA survival rates
differ greatly between different
hospitals, which led to calls for action from the Institute of
Medicine (Josey et al., 2018).
Nursing staff are not as confident or comfortable as they would
like to be when using the
Basic Life Support/Advanced Cardiac Life Support (BLS/ACLS) skills
in a true code situation
(Herbers & Heaser, 2016). Nurses experience high levels of
anxiety and have difficulty recalling
the knowledge and demonstrating the skills required during medical
emergencies (Herbers &
Heaser, 2016).
The overarching purpose of this QI project is to analyze and
evaluate the data obtained
from the results of the MCSES survey to develop a needs assessment
for the implementation of
an ISMC simulation training program. The program goal is to
optimize simulation training to
help improve nurses’ perception of self-efficacy and increase
knowledge and skills during a code
situation.
Background and significance
It is clear that mortality from IHCA remains a large problem in the
United States
(Risaliti, Evans, Buehler, Besecker, Ali, 2018). Code situations
can be very demanding and
emotionally charged (Williams et al., 2016).
One study reported that the skills gained from these training
methods steadily deteriorate
in as little as two weeks followed by a substantial reduction in
these skills within six months of
training (Herbers & Heaser, 2016). ACLS skills decrease at a
faster rate than BLS skills. The
AHA recognizes the need for additional training, stating that along
with BLS/ACLS,
organizations should provide periodic reinforcement or refresher
courses for periodic assessment
of staff members’ knowledge and skills (Herbers & Heaser,
2016).
One disadvantage of formal BLS/ACLS training class is the little
similarity it has to
resuscitation in the hospital setting. At the Mayo Clinic, nurses
and nursing assistants are
required to validate proficiency of emergency medical response and
proper use of equipment on
a regular basis during competency evaluations. This program is
designed to validate knowledge
and skills, but does not provide a learning opportunity for the
nursing staff to have hands-on
practice with the skills and knowledge needed during a code
(Herbers & Heaser, 2016). This is a
limitation of the current training and competency within different
systems.
During BLS/ACLS training courses, knowledge gained without
successive reinforcement
begins to decrease almost immediately and may be actually lost
within three months. The value
of reinforcement by repetitive training is well documented in the
clinical literature on CPR and is
the basis of the AHA’s current Resuscitation Quality Improvement
Program (Josey et al., 2018).
Team training and communication are also an area of focus for IHCA
success. The AHA
2013 consensus statement endorsed that providers promote a
coordinated team response which
includes certain role responsibilities for each team member
(Spitzer, Evans, Buehler, Ali, &
8 IN SITU MOCK CODE SIMULATION
Besecker, 2019). This would help to ensure high quality CPR and to
minimize pauses in
compressions. Despite this recommendation, descriptions of
in-hospital resuscitation teams with
specific roles and responsibilities are lacking (Spitzer et al.,
2019). Lack of clear code team
organization and communication is a regularly indicated problem
within true code and mock
code events. In order to improve this aspect of code blue
resuscitation situations, more emphasis
should be placed on educating code team members about specific
roles and responsibilities
(Josey et al., 2018).
The importance of sustained and frequent ISMC training is supported
by the observation
that ample potential for improved BLS/CPR performance persists
despite more than five years of
effort to reform practice (Josey et al., 2018). The actual
requirement for CPR recertification
every two years has recently been questioned. Currently, the use of
more frequent learning
sessions are being assessed and employed. The optimal interval in
between training sessions to
maintain a consistent proficiency level is still an active area of
on-going research (Josey et al.,
2018).
In the study performed by Josey et al. (2018), a beneficial
association was demonstrated
between increased ISMC training and patient survival in a
multihospital healthcare system. The
use of mock code simulation can improve nurses’ confidence by
repetition, allowing nurses to
evaluate their progress and increase their self-efficacy by making
the nurses more confident in
their ability to perform CPR skills.
Self-efficacy has been linked to improved nursing performance
(Oetker-Black & Davis,
2019). Although CPR is a necessary element of nursing education,
there is limited research on
the role of self-efficacy in the performance of resuscitation
skills in a clinical setting (Oetker-
Black & Davis, 2019). Students with low levels of self-efficacy
disclosed higher levels of stress
when working in a health care environment (Oetker-Black &
Davis, 2019). Unfortunately, there
9 IN SITU MOCK CODE SIMULATION
are limited studies on mock code simulation in nurses and
self-efficacy as a predictor of success
in enacting CPR skills.
Despite advances in CPR and widespread life-support training
programs, the outcomes of
resuscitation are fluctuating. There is an actual need for
organizational improvement to
strengthen the resuscitation process (Sodhi, Singla, Shrivastava,
2014). The purpose of this QI
project was to analyze and evaluate the data obtained from the
results of the MCSES survey to
develop a needs assessment for the implementation of an ISMC
simulation training program. The
overall project goal will be to optimize simulation training to
help improve nurses’ perception of
self-efficacy and increase knowledge and skills during a code
situation.
The project objectives were to: 1) establish a baseline needs
assessment using the data
from the MCSES survey in order to identify needs and deficits in
CPR skills that can be included
in future simulation training; 2) identify gaps in practice to
refine mock codes to reflect
necessities discovered in the needs assessment; and 3) enhance
training related to the needs
assessment.
The DNP Essentials
This DNP project meets the American Association of Colleges of
Nursing (2006) DNP
Essentials II and III. DNP Essential II, Organizational and Systems
Leadership for Quality
Improvement and Systems Thinking, is addressed through the project
deliverable of a Mock
Code Squad team using refined simulation training based on the
needs assessment discoveries
with the ultimate endeavor of improving nurses’ self-efficacy
during a code situation. DNP
Essential III, Clinical Scholarship and Analytical Methods for
Evidence-Based Practice, is
addressed through conducting a review of existing evidenced-based
literature and identifying
gaps in knowledge and best practice standards to demonstrate the
benefits of ISMCs to assist in
10 IN SITU MOCK CODE SIMULATION
formulating this project. There is also data collection,
statistical data analysis, and dissemination
of findings that focus on analytical methods.
Theoretical framework
The theoretical framework that is most appropriate for this study
is Albert Bandura’s
Self-Efficacy Theory that originated from his Social Cognitive
Theory. Self-efficacy is defined
as people’s judgement of their ability to execute courses of action
to complete certain types of
performances (Oetker-Black & Davis, 2019). This theory defines
self-efficacy in two
components: outcome expectations and efficacy expectations. Outcome
expectations are defined
as a person’s conclusion that a certain behavior will lead to a
given outcome; and efficacy
expectations are the notions that one can successfully complete a
task (Oetker-Black & Davis,
2019). Self-efficacy measures target performance proficiencies that
are situation specific.
The self-efficacy theory is centered on the principal belief that
psychological procedures,
serve as means of developing and augmenting expectations of
personal efficacy (Bandura, 1977).
For this study, the psychological construct of self-efficacy will
be developed by obtaining new
knowledge and skills through simulation. People fear and tend to
avoid intimidating situations
that they believe surpass their coping skills, whereas they will
participate in activities in which
they judge themselves as confident (Bandura, 1977). Bandura (1977)
states that efficacy
expectations influence how much effort people will dedicate and how
long they will pursue when
faced with obstacles and undesired experiences. Therefore, the
stronger the perceived self-
efficacy, the more productive the efforts may be as a direct effect
of increased confidence
(Bandura, 1977).
According to Bandura (1977), expectations of personal efficacy are
based on four sources
of information: (1) performance accomplishments; (2) vicarious
experience; (3) verbal
persuasion; and (4) physiological states. Performance
accomplishments are important because
11 IN SITU MOCK CODE SIMULATION
repeated success of personal mastery leads to strong self-efficacy
(Bandura, 1977). Vicarious
experience is a valuable element as some expectations are derived
from ancillary activities.
Observing others' performance can assist in proficiency improvement
by persuading themselves
that if others can do it, they should be able to attain the same
outcome (Bandura, 1977). Verbal
persuasion can influence a person’s behavior through suggestion
that they are able to
successfully cope during a stressful situation (Bandura, 1977).
Emotional arousal increases
during challenging and nerve-wracking events. This physiological
concept can be a valuable
source of information that can affect perceived self-efficacy in
overcoming anxiety during these
types of circumstances (Bandura, 1977).
This theoretical framework emphasizes the need for effective
learning in nursing to yield
high self-efficacy. This thinking coincides with simulation
training in nursing education to
improve nurses’ perception of self-efficacy as a predictor of
success, as students with low levels
of self-efficacy have reported higher levels of stress when working
in the healthcare environment
(Oetker-Black & Davis, 2019).
A lack of conceptual understanding may be why students cannot
routinely convert skills
from past experiences in simulation settings to real patients in
the clinical setting (Oetker-Black
& Davis, 2019). This self-efficacy theory could provide a
measure for knowledge regarding
CPR skills (Oetker-Black & Davis, 2019).
Review of the literature
Simulation-based health care education
Simulation-based medical education is an emerging field that
empowers students and
trainees to practice skills, augment knowledge, and develop
self-confidence in a safe and
controlled environment with no risk to patients (Williams et al.,
2016). The complexity and
capacity of simulation-based learning programs have increased
substantially over the last decade,
12 IN SITU MOCK CODE SIMULATION
as there has been a significant growth in the use of simulation to
educate health care
professionals (Roussin & Weinstock, 2017). During the past 10
years, the United States and
other regions have supported the use of simulation-based education
as a substitute for traditional
clinical time for undergraduate nursing students (Doolen et al.,
2016).
In the 2014 landmark study by the National Council of State Boards
of Nursing
(NCSBN), the authors discovered that up to a 50% substitution of
traditional clinical time with
high-fidelity simulation (HFS) yielded no statistically significant
differences in outcomes from
those with more conventional methods of clinical hours (INACSL
Standards of Best Practice:
SimulationSM Simulation Design, 2016). According to the authors,
the optimal way to facilitate
quality simulation is to integrate best practices into a simulation
program (Hayden, Smiley,
Alexander, Kardong-Edgren, & Jeffries, 2014). Hayden et al.
(2014) discovered the effectiveness
of both clinical and simulation hours as educational methods that
can lead to positive and
successful student outcomes.
Code blue situations can be very challenging and highly emotional,
which can lead to
intense interpersonal exchange. Therefore, practice in a regulated
environment can be
advantageous for both nursing students and nurses. Ultimately, this
can facilitate improved
provider confidence, as well as improved patient safety and
outcomes (Williams et al., 2016).
Responder performance
The nurse’s role as a first responder in cardiac arrest situations
is critical to patient
survival (Chu, 2018). Studies reveal that after CPR training,
nurses’ CPR skills increase from
9.42% to 78.3%; meanwhile, three months after CPR training, nurses’
CPR skills mean score
decreased from 78.3% to 67.8% (Chu, 2018). Therefore, these types
of nursing skills require
continuous practice to ensure individuals can perform competently
and consistently (McPhee,
2018).
13 IN SITU MOCK CODE SIMULATION
Clarke et al. (2018) conducted a prospective study of ISMCs at a
single teaching hospital.
This study was a training initiative that simulated mock codes 2-3
times per month on
Medical/Surgical and Telemetry floors throughout the hospital. The
authors calculated a CPR
fraction by dividing the cumulative time that the manikin received
chest compressions by the
total pulseless time. Clarke et al. observed a significant
improvement in CPR fraction over the
course of the program.
The implementation of in-hospital resuscitation teams is another
method to help improve
team training and communication during a cardiac arrest. In the
retrospective comparison study
of pre- and post-intervention implementation metrics by Spitzer et
al. (2019), they discovered
that by developing a “pit crew” model for IHCA resuscitation, they
could improve code team
performance. The authors discovered that this model showed
statistically significant
improvements in compression rates and team communication
post-intervention, as well as a
trend toward a reduction in the number of shockable rhythms that
were not defibrillated.
High-quality CPR positively affects patient survival rates, but it
is well-established that
CPR skills deteriorate overtime. A solution to this issue is
regular practice of CPR skills. ISMCs
is an effective way to maintain competency of these life-saving
skills (Chu, 2018).
Confidence levels
Deteriorating patient situations can be anxiety triggering
situations for new graduate
nurses (McPhee, 2018). McPhee (2018) decided to trial deliberate
mock codes in a nurse
residency program which allowed them extra time in small groups to
be able to practice mock
codes multiple times, as well as fix mistakes. The author set up
simulation experiences for small
groups, in which they practiced a scenario multiple times and
rotated roles, followed by a
debriefing. The nurse residents (NRs) shared that they found the
deliberate mock code practice to
be valuable. One hundred percent of the NRs felt that the
simulation allowed them to build their
14 IN SITU MOCK CODE SIMULATION
knowledge and help them gain confidence in their ability to manage
their response to a declining
patient.
Herbers and Heaser (2016) implemented a mock code quality
improvement program to
increase nurses’ confidence while enhancing their performance when
responding to medical
emergencies. For their study, in situ simulation was the method of
integration of the mock codes.
Along with a 12% improvement rate of initiating chest compressions
and delivering the first
shock, post-survey results revealed the staff members' perceived
confidence levels to initiate
chest compressions increased to 100% favorable (from 82%), and
overall confidence of
participating in a code situation increased to 98.8% (from 86.5%).
Ultimately, this shows that
mock code training leads to an increase in nurse-perceived
confidence levels.
Low self-confidence has been referenced as a barrier to performing
high-quality CPR
(Morton, Powers, Jordan, & Hatley, 2019). Mock code simulation
can increase nurses’ self-
confidence in performing in a code event. According to Morton et
al. (2019), the use of HFS
mock code training with medical-surgical nurses increases
self-confidence. In the quasi-
experimental study by Morton et al., the mean self-confidence score
significantly increased from
32.2 to 38.7 of 40 after HFS code training. It is important to
acknowledge that providing nurses
with opportunities for recurrent practice is valuable in order to
improve self-confidence (Morton
et al., 2019).
IHCA survival outcomes
IHCA outcomes differ in hospitals across the United States.
Nallamothu et al. (2018)
interviewed 158 individuals across nine different hospitals,
including physicians, nurses, other
clinical staff, and administration to discover how top hospitals
organize their resuscitation teams
to achieve high IHCA survival rates. The authors identified four
themes: (1) team design, (2)
team composition and roles, (3) communication and leadership during
IHCA, and (4) training
15 IN SITU MOCK CODE SIMULATION
and education. Nallamothu et al. discovered core elements of
designated teams, participation of
diverse disciplines, clear roles, better communication and
leadership, and in-depth mock codes
that were associated with better outcomes at top-performing
hospitals.
In 2013, the AHA and the Institute of Medicine (IOM) presented a
national “call-to-
action” to improve IHCA survival rates (Josey et al., 2018). Josey
et al. (2018) performed a
descriptive study across a 26-hospital healthcare system to assess
if there was a correlation
between more active ISMC training and increased IHCA survival.
Josey et al. were one of the
first researchers to establish a beneficial association between
increased ISMC training and
patient survival outcome after IHCA.
The education and training of hospital staff who respond to cardiac
arrest events is
essential to improving outcomes (Clarke et al., 2018). Increasing
the implementation of ISMC
training programs is one way to narrow the gap between IHCA and
patient survival outcomes.
Methods
Design
This study was a secondary analysis of data obtained from nurses
from the results of the
MCSES survey. The data was obtained as part of the hospital
setting’s Quality Improvement
(QI) committee’s actions to document the need for both expanded and
enhanced ISMC
simulation training for the staff. The analysis of the data helped
to discover and evaluate a needs
assessment with respect to ISMCs. The ultimate program goal is to
optimize simulation training
to help improve nurses’ perception of self-efficacy and increase
knowledge and skills during a
code situation.
Setting
The setting was both CC and MS floors at a large urban hospital,
which is a tertiary care
center within a network of hospitals included in a non-profit
healthcare system that provides care
in Western New York.
Subjects and Recruitment
Upon receiving full approval from the UB’s Institutional Review
Board (IRB) (Appendix
A.), the MCSES survey data was analyzed. A convenience sample was
used, as the setting’s QI
committee had already distributed the survey and collected the
results. The study’s PI is part of
the QI team at her place of employment, which was the setting for
the study. A convenience
sample was used of nurses who are employed on CC and MS floors
within the study site who
meet the following inclusion criteria a) 18 years of age and older,
b) graduated from an
accredited nursing school with an associates or baccalaureate in
nursing, and c) participated in
the MCSES survey. As part of the QI team of the setting facility,
the researcher had permission
and access to the data results from the MCSES survey answers. The
purpose of this needs
assessment was to identify gaps in knowledge related to ISMC
training to improve future ISMC
simulation education and training.
Needs Assessment to Identify Gaps in Practice with Mock Codes
Upon the code team’s arrival to code events on the MS floors, it
became very obvious
that the staff was unorganized and lacked training. The QI
committee identified multiple issues
during codes, such as lack of rescue breathing, inability to
recognize dysrhythmias, and absence
of designated team roles and structure. Therefore, the educational
department and QI committee
devised a plan to survey nurses to understand the nurses’ current
skill set and identify knowledge
17 IN SITU MOCK CODE SIMULATION
After identifying the gaps in knowledge related to ISMC training,
the expectation is that
with the information obtained, future educators are able to
optimize mock code simulation
training by formulating the code scenarios based on the results and
disparities discovered from
the needs assessment data.
Data Collection
Study variable. The main variable of this study was nurses’
self-efficacy. The variables
that were under study to determine nurses’ self-efficacy were 12
clinical skill items:
1. How confident are you at assessing and identifying a patient in
respiratory failure?
2. How confident are you at assessing and identifying a patient
with no pulse?
3. How confident are you at providing rescue breathing for a client
with a pocket mask or
resuscitation bag?
4. How confident are you at initiating chest compressions for a
client without a pulse?
5. How confident are you at recognizing bradycardia on the cardiac
monitor?
6. How confident are you at recognizing tachycardia on the cardiac
monitor?
7. How confident are you at recognizing asystole on the cardiac
monitor?
8. How confident are you at recognizing ventricular fibrillation on
the cardiac monitor?
9. How confident are you at recognizing pulseless ventricular
tachycardia on the cardiac
monitor?
10. How confident are you at identifying which dysrhythmias would
require an
unsynchronized shock (defibrillation) in cardiopulmonary
arrest?
11. How confident are you at naming the first medication given to a
client in
cardiopulmonary arrest during a code blue situation.
12. How confident do you feel functioning as part of the team in a
code blue situation for
client in cardiopulmonary arrest?
18 IN SITU MOCK CODE SIMULATION
The 12 clinical skills were further grouped into three subscales.
Subscale 1 was EKG
recognition (items 5-9), Subscale 2 consisted of initial CPR
assessment (items 1-4), and Subscale
3 contained items of action during a code (items 10-12). The visual
analog scale answers ranged
from 0 to 10 with 0 being “No Confidence” and 10 being “Total
Confidence”. There were two
main comparison groups under study to determine if the levels of
confidence between them were
statistically significant; (1) CC nurses versus MS nurses and (2)
nurses with PMCE versus nurses
without.
Demographic tool. The first part of the survey was a demographic
tool that was a total of
four questions defining different characteristics of the
participants (Appendix B). Four
demographic questions were included in this section of the
questionnaire: (1) How many years
have you been working as a nurse?, (2) What gender do you identify
as?, (3) What unit do you
currently work on?, and (4) Do you have past experience with mock
codes? This information
was used to delineate differences in the unit trained/skill level
of the nurse in order to separate
into the following groups; (1) unit and (2) PMCE. It also allowed
the researcher to define other
characteristics, such as years experience as a nurse,
Measurement tool. The measurement tool used for this study was the
Mock Code Self-
Efficacy Scale (MCSES) adapted from Oetker-Black and Davis (2019)
(see Appendix C).
Permission has been granted by the author of the tool to use the
tool for this study (see Appendix
D). The tool consists of 12 questions on clinical skills, listed
above. The MCSES is a
standardized tool that is shown to have reliability, face, and
content validity. Reliability using
Cronbach’s alpha was calculated for the three subscales: a) EKG
recognition 0.87, b) initial CPR
assessment 0.82, and c) actions during code 0.75 (Oetker-Black
& Davis, 2019). Face validity
was established by five senior undergraduate nursing students and
no confusing questions were
identified (Oetker-Black & Davis, 2019). Content validity was
established by two experts who
19 IN SITU MOCK CODE SIMULATION
actively teach CPR skills, and evaluated each item for relevance,
clarity, and sufficiency (Oetker-
Black & Davis, 2019). A content validity index was used to rate
the relevance of each item using
a 4-point scale. All the items received a score of either 3 or 4 by
the experts, which indicated that
all the items had content validity (Oetker-Black & Davis,
2019).
The data were collected as part of a mandatory education assignment
for the nurses that
included a short video and PowerPoint presentation followed by the
survey. The data collection
was via an online learning platform that the facility’s education
department uses for continuing
education for the staff.
Data analysis was conducted using Statistical Package for Social
Sciences (SPSS). The
analysis was a combination of both descriptive and inferential
statistics. Initially using
descriptive statistics, the overall frequencies for self-efficacy
related to the 12 clinical skills and
four demographic questions were analyzed using the complete sample
for baseline data. Using
inferential statistics, there were two steps of data analysis
comparisons. The two main
comparison groups under study were: (1) CC versus MS nurses and (2)
nurses who have had
PMCE versus nurses who have not. Independent t-tests were performed
to compare the self-
efficacy of group differences. The analysis of data determined if
there were differences in
nurses’ self -efficacy regarding mock codes when compared by work
unit and PMCE.
Comparison group one: Units. The first section was the comparison
of CC versus MS
nurses. The sample was divided into two groups by their work unit.
There was a total of 12 units;
nine MS units (4N, 5E, 5NC, 5W, 6E, 6W, 7E/8E, Float, MRU) and
three CC units (CVICU,
ICU, ED). Therefore, this grouping variable was reduced to CC
versus MS nurses. Data analysis
comparison of the unit grouping variable was completed using both
question sets; (1) 12 clinical
20 IN SITU MOCK CODE SIMULATION
skills and (2) three subscales. They were compared to see if there
was a statistical difference
between the groups and levels of confidence of each of the question
sets.
A chi-squared association table was also examined to analyze the
relationship between
units and PMCE to determine if working on either CC or MS units
increased nurses’ PMCE.
Comparison group two: PMCE. The second section was a comparison of
nurses who
have had PMCE versus nurses who have not had PMCE using the
complete sample. Data
analysis comparison of the PMCE grouping variables was completed
using both question sets;
(1) 12 clinical skills and (2) three subscales. They were compared
to see if there was a statistical
difference between the groups and levels of confidence of each of
the question sets.
A final analysis was completed comparing years of experience as a
nurse to PMCE to
examine if the nurses with more years of experience were more
likely to have PMCE.
The information acquired determined if the levels of confidence
were statistically
significant between the groups. This data was used to answer the
following research questions:
(1) Are CC trained nurses more confident than MS nurses in the 12
clinical skills?, (2) Do CC
nurses have more experience than MS nurses with mock codes?, (3) Do
nurses with PMCE have
increased confidence in the 12 clinical skills?, (4) Are nurses
with greater years of experience
more likely to have PMCE?, and (5) What are the specific clinical
skills in each group
comparison that have the lowest confidence scores?.
The overall data provided the development of a needs assessment to
identify gaps in
knowledge related to ISMC training in nursing practice. The
ultimate goal of this project was to
development a needs assessment in order to optimize future
simulation training and education to
help improve nurses’ perception of self-efficacy and increase
knowledge and skills during a code
situation.
Results
There was a total of 311 nurses surveyed. Some participants did not
answer all of the
questions, which will be described below. The answers ranged from 0
to 10 with 0 being “No
Confidence” and 10 being “Total Confidence” on a visual analog
scale.
Descriptive statistics were used to analyze the total scores of
each of the four
demographic questions. The years of experience as a nurse ranged
from 0-45 years with 11.75
the average number of years (n=293). There were 18 (5.8%) missing
answers for this question.
There were 267 (85.9%) females and 27 (8.7%) males (n=294). There
were 17 (5.5%) missing
answers for this question. Of the 311 nurses, 77 (24.8%) work on a
CC unit and 146 (46.9%)
work on a MS unit (n=223). There were 88 (28.3%) missing answers
for this question. Of the
292 nurses who answered the PMCE question, there were 170 (58.2%)
nurses that had PMCE,
while 122 (41.8%) nurses did not. There were 19 (6.1%) missing
answers for this question.
Descriptive statistics were then used to analyze the total scores
of each of the individual
items. For each of the 12 clinical skill questions between 273-277
nurses answered each question
out of the total 311 nurses surveyed.
Comparison Group One: Units
Using an independent t-test, the first comparison analyzed CC
versus MS nurses (after
the total sample was divided into two groups by unit) using both
question sets; (1) 12 clinical
skills and (2) three subscales. In 11 of the 12 clinical skills,
there was a significant difference in
confidence scores between CC and MS nurses, as outlined in Table 1.
Clinical skill question
number seven, “Recognizing asystole on the cardiac monitor”, was
the only clinical skill that did
NOT have a significant difference in scores between CC and MS
nurses.
[Insert Table 1 about here]
22 IN SITU MOCK CODE SIMULATION
Next a comparison of CC versus MS nurses using the three subscales
was examined. In
all three subscales, there was a significant difference in
confidence scores between CC and MS
nurses, as outlined in Table 2.
[Insert Table 2 about here]
The final part of the group one comparison was an analysis of a
chi-squared test that
discovered a statistically significant association between units
and PMCE; x2(1)=8.919, p=.003,
as outlined in Table 3.
[Insert Table 3 about here]
Comparison Group Two: PMCE
Using an independent t-test, the second comparison analyzed nurses
who have had
PMCE versus nurses who have not had PMCE (after the total sample
was divided into two
groups by PMCE) using both question sets; (1)12 clinical skills and
(2) three subscales. In all 12
clinical skills, there was a significant difference in confidence
scores between nurses who have
had PMCE versus nurses who have not, as outlined in Table 4.
[Insert Table 4 about here]
Next a comparison of nurses who have PMCE versus nurses who have
not had PMCE
using the three subscales was examined. In all three subscales,
there was a significant difference
in confidence scores between nurses who have had PMCE versus nurses
who have not, as
outlined in Table 5.
[Insert Table 5 about here]
The final analysis compared years of experience as a nurse to PMCE.
There was a
significant difference in years of nursing experience for those who
have had PMCE (M=15.3054,
SD=12.638) and those who have not had PMCE (M=6.5657, SD 9.614);
t(280)=6.322, p=.000.
23 IN SITU MOCK CODE SIMULATION
Discussion
Total Sample Analysis
When comparing the total sample, the three skills that had the
lowest level of confidence
were (1) Question 10: Identify which dysrhythmias would require an
unsynchronized shock
(defibrillation) in cardiopulmonary arrest (M=6.72), (2) Question
11: Name the first medication
given to a client in cardiopulmonary arrest during a code blue
situation (M=7.18), and (3)
Question 9: Recognize pulseless ventricular tachycardia on the
cardiac monitor (M=7.49).
Missing data. It is unclear why some of the respondents did not
answer all of the
demographic questions. It may be that the participants did not find
an answer that accurately
reflects their description. The respondents may not have been
understanding of the legitimate
purpose of their answers or were afraid of repercussions.
Fortunately, the sample size was large
enough that the data analysis was unaffected by the missing
answers.
Comparison Group One: Units
In all, but one, of the clinical skills, CC nurses had an increased
level of confidence over
MS nurses. The only clinical skill that was not statistically
significant was recognizing asystole.
Hence, CC and MS nurses felt equally confident at recognizing
asystole on the cardiac monitor.
When comparing the CC versus MS nurse analysis, the three skills
that had the lowest
level of confidence in CC nurses were (1) Question 10: Identify
which dysrhythmias would
require an unsynchronized shock (defibrillation) in cardiopulmonary
arrest (M=8.44), (2)
Question 11: Name the first medication given to a client in
cardiopulmonary arrest during a code
blue situation (M=8.71), and (3) Question 1: Identify and assess a
client in respiratory failure
(M=8.93). The three skills that had the lowest level of confidence
in MS nurses were (1)
Question 10: Identify which dysrhythmias would require an
unsynchronized shock
(defibrillation) in cardiopulmonary arrest (M=5.80), (2) Question
11: Name the first medication
24 IN SITU MOCK CODE SIMULATION
given to a client in cardiopulmonary arrest during a code blue
situation (M=6.62), and (3)
Question 9: Recognize pulseless ventricular tachycardia on the
cardiac monitor (M=6.82).
When comparing CC versus MS and the three subscales, CC nurses had
greater
confidence levels than MS nurses in all three subscales. The subset
that had the lowest
confidence levels in both CC and MS nurses was “Actions During
Code”. This subset includes
questions 10-12, which includes the two of the three clinical
skills that have the lowest
confidence levels of both CC and MS nurses.
Comparison Group Two: PMCE
When comparing the confidence levels of participants who have had
PMCE to those who
have not, those who have had PMCE were more confident in all 12
skills. Of the 12 clinical
skills, the three that had the greatest difference of means were
(1) Question 10: Identify which
dysrhythmias would require an unsynchronized shock (defibrillation)
in cardiopulmonary arrest
(MD=2.67), (2) Question 9: Recognize pulseless ventricular
tachycardia on the cardiac monitor
(MD=2.23), and (3) Question 11: Name the first medication given to
a client in cardiopulmonary
arrest during a code blue situation (MD=2.11). Whether or not the
nurse had PMCE, the three
clinical skills with the lowest confidence level were the same
between the two groups. Of note,
these were the same three clinical skills that had the lowest
levels of self-confidence in MS
nurses also.
When comparing nurses who had PMCE versus those who did not in
regard to the three
subscales, nurses who had PMCE had greater confidence levels than
those without in all three
subscales. The subset that had the lowest confidence levels in both
nurses who had PMCE and
those who did not have PMCE was “Actions During Code”. This subset
includes the questions
10-12, which again includes the same two clinical skills that have
the lowest confidence levels of
the total sample, CC nurses, MS nurses, nurses with PMCE, and
nurses with no PMCE.
Total Group Comparison
Upon summarization of all the group comparisons, including the
total sample, CC nurses,
MS nurses, and PMCE, there are two clinical skills that are in each
of the groups as having the
lowest confidence levels (1) Question 10: Identify which
dysrhythmias would require an
unsynchronized shock (defibrillation) in cardiopulmonary arrest,
and (2) Question 11: Name the
first medication given to a client in cardiopulmonary arrest during
a code blue situation. In the
total sample, MS nurses, nurses with PMCE, and nurses with no PMCE
groups, question nine
“Recognize pulseless ventricular tachycardia on the cardiac monitor
and upon assessment of the
client” was also recognized as having lower confidence level in the
above three groups.
These clinical skills that have the lowest confidence levels are
gaps in knowledge as the
nurses felt the least amount of confidence performing them. Future
ISMC simulation training
scenarios should be refined to focus on these gaps in practice.
Mock codes should be optimized
to reflect this need by implementing scenarios that incorporate
these skills.
When comparing years of experience as a nurse to PMCE, it was
determined that nurses
with more years of experience had increased PMCE. This fact is not
surprising, as a nurse is
more likely to encounter mock codes the longer that they have been
a nurse. It was also
discovered that nurses who work on CC units have increased PMCE.
This provides a rationale
for the need for additional ISMC training on MS floors.
Strengths and Limitations
A strength of this study was that it had a large sample size. The
data analysis revealed a
robust number of statistically significant outcomes. The
measurement tool that was used to
survey the nurses was a standardized tool. This project was
originally initiated by the QI
committee which provided the researcher access to data. A
limitation of this study was the
26 IN SITU MOCK CODE SIMULATION
missing demographic information that lead to participant data being
unusable. Another limitation
was this was a secondary data analysis.
Future Implications
The results of the study revealed that MS nurses overall had
decreased confidence levels
in skill assessment and were less likely to have PMCE than CC
nurses. Nurses with PMCE were
more confident in performing the clinical skills that those without
PMCE. Therefore, mock codes
should be performed routinely on MS units to improve mock code
experience and increase
confidence while performing in code situations. Optimization of
ISMCs should include the
clinical skills identified that the nurses felt the least amount of
confidence performing to yield
full benefit. A component of the improvement of ISMCs would be to
develop and implement
scenarios that included the skills that had the lowest confidence
levels.
Dissemination of the Results
The final results of the project were disseminated to stakeholders
with discussion
regarding the strengths and limitations of the study, as well as
potential future implications of
continued ISMC training. The findings were presented to the
facility’s education and QI
committee and faculty committee members to show how simulation can
be optimized and how
the application of continued scheduled mandatory in-services of
ISMC simulation training and
practice should be encouraged. This paper will also be submitted
for publication.
Conclusion
In-situ simulation is one answer that could help to improve staff
members’ confidence,
skills, and knowledge, while improving patient outcomes after an
IHCA. Mock code training
offers an opportunity to identify and analyze issues with the
existing code process. In this study,
a need for increased ISMC training for MS nurses and optimization
of simulation scenarios were
identified. The use of revised mock code simulations can improve
nurses’ confidence and
27 IN SITU MOCK CODE SIMULATION
performance by repetition, allowing nurses to evaluate their
progress and make necessary
practice changes during an emergency situation.
28 IN SITU MOCK CODE SIMULATION
References
American Association of Colleges of Nursing. (2006). The essentials
of doctoral education for
advanced nursing practice.: Author.
Bandura, A. (1977). Self-efficacy: Toward a unifying theory of
behavioral change.
Psychological Review, 84(2), 191–215. doi:
10.1037/0033-295x.84.2.191
Chu, R., & Robilotto, T. (2018). Mock code training to enhance
CPR skills. Nursing Made
Incredibly Easy!, 16(2), 11-15.
http://dx.doi.org/10.1097/01.nme.0000529957.11904.8d
Clarke, S. O., Julie, I. M., Yao, A. P., Bang, H., Barton, J. D.,
Alsomali, S. M., … Bair, A. E.
(2018). Longitudinal exploration of in situ mock code events and
the performance of
cardiac arrest skills. BMJ Simulation and Technology Enhanced
Learning, 5(1), 22–26.
http://dx.doi.org/10.1136/bmjstel- 2017-000255
Doolen, J., Mariani, B., Atz, T., Horsley, T. L., Rourke, J. O.,
Mcafee, K., & Cross, C. L. (2016).
High-fidelity simulation in undergraduate nursing education: A
review of simulation
reviews. Clinical Simulation in Nursing, 12(7), 290–302. doi:
10.1016/j.ecns.2016.01.009
Hayden, J. K., Smiley, R. A., Alexander, M. R., Kardong-Edgren, S.,
& Jeffries, P. (2014). The
NCSBN National Simulation Study: A longitudinal, randomized,
controlled study
replacing clinical hours with simulation in prelicensure nursing
education. Journal of
Nursing Regulation, 5(2). doi: 10.1016/s2155-8256(15)30062-4
Herbers, M. D., & Heaser, J. A. (2016). Implementing an in situ
mock code quality
improvement program. American Journal of Critical Care, 25(5),
393–399.
http://dx.doi.org/10.4037/ajcc2016583
http://dx.doi.org/10.1016/ j.ecns.2016.09.005.
Josey, K., Smith, M. L., Kayani, A. S., Young, G., Kasperski, M.
D., Farrer, P., … Raschke, R.
A. (2018). Hospitals with more-active participation in conducting
standardized in-situ
mock codes have improved survival after in-hospital cardiopulmonary
arrest.
Resuscitation, 133, 47–52.
http://dx.doi.org/10.1016/j.resuscitation.2018.09.020
Mcphee, K. (2018). Deliberate practice mock codes for new graduate
nurses. Journal for Nurses
in Professional Development, 34(6), 348-351.
http://dx.doi.org/10.1097/nnd.0000000000000494
Morton, S.B., Powers, K., Jordan, K., & Hatley, A. (2019). The
effect of high-fidelity simulation
on medical-surgical nurses’ mock code performance and
self-confidence. Medsurg
Nursing, 28(3), 177-182.
Nallamothu, B. K., Guetterman, T. C., Harrod, M., Kellenberg, J.
E., Lehrich, J. L., Kronick, S.
L., … Chan, P. S. (2018). How do resuscitation teams at
top-performing hospitals for
in-hospital cardiac arrest succeed? Circulation, 138(2), 154–163.
doi:
10.1161/circulationaha.118.033674
Oetker-Black, S. L., & Davis, T. (2019). Psychometric
evaluation of the Mock Code
Self-Efficacy Scale. Nursing Education Perspectives, 40(1),
35–40.
http://dx.doi.org/10.1097/01.nep.0000000000000341
Risaliti, C., Evans, K., Buehler, J., Besecker, B., & Ali, N.
(2018). Decoding Code Blue: A
process to assess and improve code team function.
Resuscitation,
122. http://dx.doi.org/10.1016/j.resuscitation.2017.11.039
Roussin, C. J., & Weinstock, P. (2017). SimZones: An
organizational innovation for simulation
programs and centers. Academic Medicine, 92(8), 1114–1120.
doi:
Sodhi, K., Singla, M. K., & Shrivastava, A. (2014).
Institutional resuscitation protocols: Do they
affect cardiopulmonary resuscitation outcomes? A 6-year study in a
single tertiary-care
centre. Journal of Anesthesia, 29(1), 87–95.
http://dx.doi.org/10.1007/s00540-014-1873-z
Spitzer, C. R., Evans, K., Buehler, J., Ali, N. A., & Besecker,
B. Y. (2019). Code blue pit crew
model: A novel approach to in-hospital cardiac arrest
resuscitation. Resuscitation, 143,
158–164.
http://dx.doi.org/10.1016/j.resuscitation.2019.06.290
Williams, K., Rideout, J., Pritchett-Kelly, S., Mcdonald, M.,
Mullins-Richards, P., & Dubrowski,
A. (2016). Mock Code: A code blue scenario requested by and
developed for registered
nurses. Cureus. http://dx.doi.org/10.7759/cureus.938
Table 1
Critical Care
Critical Care
1.657 2.744 192 .002
3 Provide rescue breathing for a client with a pocket mask or
resuscitation bag
Critical Care
4 Initiate chest compressions for a client without a pulse
Critical Care
Critical Care
Critical Care
Critical Care
Critical Care
Critical Care
Critical Care
32 IN SITU MOCK CODE SIMULATION
11 Name the first medication Critical Care 68 8.71 2.081 given to a
client in 4.855 186 .000 cardiopulmonary arrest Med-Surg 130 6.62
3.199 during a code blue situation
12 Function as part of the team Critical Care 68 9.26 1.378 in a.
code blue situation for 5.998 195 .000 client in cardiopulmonary
Med-Surg 130 7.22 2.622 arrest
*=missing one observation
Table 2
EKG recognition Critical Care 68 46.62 6.015
Med-Surg 130 41.28 9.507
Med-Surg 130 32.93 6.779
Med-Surg 130 19.60 7.248
Table 3
Association Analysis of Unit Versus Past Mock Code Experience
(N=223) Past Mock Code Experience Yes No
Total
Table 4
Past Mock Code Experience Grouping Statistics of 12 Clinical Skills
(N=259)
# Clinical Skill PMCE n Mean SD t df Sig
1 Assess and identify a client in respiratory distress
Yes
No
151
108*
8.74
7.23
1.692
Yes
No
151
108*
9.46
8.55
.998
1.921 5.001 148 .000
3 Provide rescue breathing for a client with a pocket mask or
resuscitation bag
Yes
No
149**
109
8.91
7.61
1.475
4 Initiate chest compressions for a client without a pulse
Yes
No
150*
109
9.33
8.17
1.150
Yes
No
150*
108*
9.55
8.44
1.046
Yes
No
150*
107**
9.59
8.51
.970
Yes
No
149**
108*
9.63
8.75
1.029
Yes
No
150*
108*
8.88
6.96
1.843
Yes
No
151
108*
8.42
6.19
2.192
Yes
No
150*
109
7.83
5.16
2.499
36 IN SITU MOCK CODE SIMULATION
11 Name the first medication Yes 151 8.10 2.729 given to a client
in 5.586 199 .000 cardiopulmonary arrest during No 107** 5.99 3.318
a code blue situation
12 Function as part of the team in Yes 151 8.68 1.852 a code blue
situation for client 6.878 257 .000 in cardiopulmonary arrest No
108* 6.62 2.963
*=missing one observation **=missing tow observations
37 IN SITU MOCK CODE SIMULATION
Table 5
Inferential Statistics of Subscales by Past Mock Code Experience
(N=260)
Subscale PMCE n Mean SD t df Sig
EKG recognition Yes
Appendix A
University at Buffalo Institutional Review Board (UBIRB) Office of
Research Compliance | Clinical and Translational Research Center
Room 5018
875 Ellicott St. | Buffalo, NY 14203 UB Federalwide Assurance ID#:
FWA00008824
NOT HUMAN RESEARCH DETERMINATION
December 10, 2020
Dear Nicole Wedzina,
On 12/10/2020, the University at Buffalo IRB reviewed the following
submission:
Type of Review: Initial Study Title of Study: Evaluating nurses'
self-efficacy related to in situ mock
codes (ISMC) simulation training Investigator: Nicole Wedzina
IRB ID: STUDY00005050 Funding: None Grant ID: None
IND, IDE, or HDE: None Documents Reviewed: • Appendix G-Permission
to use MCSES.docx, Category:
Other; • NWedzina-ISMC and nurses' self-efficacy project, Category:
IRB Protocol; • Oetker-Black validated survey tool.pdf, Category:
Surveys/Questionnaires;
The IRB determined that the proposed activity is not research
involving human subjects. IRB review and approval is not
required.
This determination applies only to the activities described in the
IRB submission and does not apply should any changes be made. If
changes are being considered and there are questions about whether
IRB review is needed, please submit a study modification to the IRB
for a determination. You can create a modification by navigating to
the initial submission and selecting ‘Create Modification /
CR’.
If you have questions, please contact the UBIRB at 716-888-4888 or
[email protected]. Please include the project title and number in
all correspondence with the UBIRB.
Page 1 of 1
Appendix B
______________________
Appendix B Mock Code Self-Efficacy Scale: Part A Demographics
A. Demographic Information
1. How many years have you been working as a nurse?
2. What gender do you identify as? a. Male b. Female c. Prefer not
to answer
3. What unit do you currently work on? a. 4N b. 5E c. 5W d. 5NC e.
6E f. 6W g. 7E/8E h. 7W i. MRU j. Float k. ED l. CVICU m. ICU n.
Prefer not to answer
4. Do you have past experience with mock codes? a. Yes b. No
42 IN SITU MOCK CODE SIMULATION
Appendix C
43 IN SITU MOCK CODE SIMULATION
Appendix C Mock Code Self-Efficacy Scale: Part B MCSES Tool
B. Mock Code Self-Efficacy Scale tool
For the following questions, please rate your confidence by
circling the designated number on a scale from 0 to 10 with 0 being
“No Confidence” and 10 being “Total Confidence”.
1. How confident are you at assessing and identifying a patient in
respiratory failure?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
2. How confident are you at assessing and identifying a patient
with no pulse?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
3. How confident are you at providing rescue breathing for a client
with a pocket mask or resuscitation bag?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
4. How confident are you at initiating chest compressions for a
client without a pulse?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
5. How confident are you at recognizing bradycardia on the cardiac
monitor?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
6. How confident are you at recognizing tachycardia on the cardiac
monitor?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
7. How confident are you at recognizing asystole on the cardiac
monitor?
44 IN SITU MOCK CODE SIMULATION
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
8. How confident are you at recognizing ventricular fibrillation on
the cardiac monitor?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
9. How confident are you at recognizing pulseless ventricular
tachycardia on the cardiac monitor?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
10. How confident are you at identifying which dysrhythmias would
require an unsynchronized shock (defibrillation) in cardiopulmonary
arrest?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
11. How confident are you at naming the first medication given to a
client in cardiopulmonary arrest during a code blue
situation?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
12. How confident do you feel functioning as part of the team in a
code blue situation for a client in cardiopulmonary arrest?
0 1 2 3 4 5 6 7 8 9 10 No Confidence Total Confidence
45 IN SITU MOCK CODE SIMULATION
Appendix D
Permission from author to use MCSES
,aj&@Rlehi February 15, 2020 at s:10 PM
[email protected]
use MCSES
To:
[email protected]
Dear Dr. Oetker-Black,
I know you are busy, so I will keep this brief.
My name is Nicole Wedzina. I am a student at the University at
Buffalo in the Post-MS DNP program. I work as an Adult Nurse
Practitioner in the N euroCritical Care unit at a local
hospital.
e
I am part of a Mock Code Squad at the facility we work at. For my
DNP project, after each simulation mode code training, I would like
to evaluate the nurses ' self-efficacy and confidence regarding
emergency code situations.
I am writing to ask permission to use the Mock Code Self-Efficacy
Scale, as in your article Psychometric Evaluation of the Mock Code
Self Efficacy Scale, you have shown that the scale has reliability,
as well as content and face validity.
Thank you for your time,
Nicole Wedzina
[email protected]
To: Wedzina, Nicole
8 +. <+. • Siri found new contact info in this email: Sharon
Black
[email protected]
You have my permission to use the scale . It may not be adapted
.
Sharon L Oetker- Black RN, Phd, JD, ANEF, FMN Professor and
Director of Nursing Research, Byers School of Nursing 2020 E Maple
Street North Canton OH 44720 (P) 330-244-4779 (E)
[email protected]
www.walsh.edu a
February 21, 2020 at 11 :42 AM
add to Contacts... ®
This message and any attachments arc intended for the individual or
entity named above. lf you arc not the intended recipient, please
do not forward, copy, print, use or disclose this communication to
others; also please notify the sender by replying to this message,
and then delete it from your system.
From: Wedzina, Nicole <
[email protected]> Sent: Saturday,
February 15, 2020 8:10 PM To: Sharon Black <~walsh.edu>
Subject: Permission to use MCSES
CAUTION: This email originated from outside of the organization. Do
not click links or open attachments unless you recognize the sender
and know the content is safe.
46 IN SITU MOCK CODE SIMULATION
Appendix D Permission from author to use MCSES
(A) Request for permission:
SIMULATION TRAINING
Background
• In-hospital cardiac arrest (IHCA) mortality remains a large
problem in the US
• Skills gained from training methods steadily deteriorate
• Self-efficacy linked to improved nursing performance
• Low levels of self-efficacy disclosed higher levels of
stress
BACKGROUND AND
Gap in Practice
• Surveyed nurses to discover skill set
• Discovered gaps in practice to efficiently and effectively
improve future In-situ
mock codes {ISMCs)
• Use of mock code simulation can:
- Improves nurses' confidence
- Improve nurses' performance
- Improve patient outcomes
strengthen the resuscitation process J::1~A ., • Establish a
baseline needs assessment (PURPO<;~,. · • Identify needs and
deficits in CPR skills
The purpose of this QI project was to analyze and 1/ • Optimize
future simulation training evaluate the data obta ined from the
results of the
MCSES survey to develop a needs assessment
for the optimization of an ISMC simulation training
program.
Research Questions
1. Are critical care (CC) trained nurses more confident than
medical-surgical (MS)
nurses in the 12 clinical skills?
2 . Do CC nurses have more experience than MS nurses with mock
codes?
3 . Do nurses with past mock code experience (PMCE) have increased
confidence in the
12 clinical skills?
4 . Are nurses with greater years of experience more likely to have
PMCE?
5 . When comparing groups, what are the clinical skills that have
the lowest confidence
scores?
Theoretical framework: Theoretical framework: Albert Bandura's
Self-Efficacy Theory Albert Bandura's Self-Efficacy Theory
• The stronger the perceived self-efficacy, the more productive the
efforts may be as a direct
effect of increased confidence • Self-efficacy:
- People's judgement of their ability to execute actions to
complete certain performances • Expectations of personal efficacy
are based on four sources of information:
- Measures target performance profi iencies that are situation
specific - (1) performance accomplishments
- (2) vicarious experience • Theory defines self-efficacy in two
components:
- (3) verbal persuasion - Outcome expectations
- (4) physiological states - Efficacy expectations
Theoretical framework: Albert Bandura's Self-Efficacy Theory
• Emphasizes need for effective learning in nursing to yield high
self-efficacy
• Coincides with simulation training
Literature review key topics
• Empowers students to practice skills, augment knowledge, and
develop self
confidence in a safe environment with no risk to patients
~-•·'·"'"'
• Facilitate improved provider confidence, and improved patient
safety and
outcomes {Wiliamlelal,2016)
• 2014 landmark study by the National Council of State Boards of
Nursing:
- 50% substitution of traditional clinical time with HFS yielded no
statistically
significant differences in outcomes from those with more
conventional
methods of clinical hours
{INACSLS1andar<lsoflle$1Praclice:$m.JlatlMSMSlmulalionDeslgn.201sJ
Responder performance
• Nurse's role as a first responder in cardiac arrest situations is
critical to patient
survival {Chu,201a1
• Nursing skills require continuous practice to ensure individuals
can perform
competently and consistently , • ..._.ro,.,
• Clarke et al. (2018) conducted a prospective study of
ISMCs:
- Training initiative that simulated mock codes
- Calculated a CPR fraction
- Observed a significant improvement over the course of the
program
IHCA survival outcomes
survival outcome after IHCA ,-•.,.ro,.,
• Education and training of staff who respond to cardiac arrest
events is
essential to improving outcomes ,o ....... ro,.,
• Increasing !SMC training programs can narrow gap between !HCA
and
patient survival outcomes ,,,, ...... ro,.,
Confidence levels • Deteriorating patient situations can be anxiety
triggering situations for new
graduate nurses {ldo:Phee,201a)
• Simulation allowed building of knowledge and confidence in
ability to manage
response to a declining patient ,..,,,,.,,.ro,.,
• Low self-confidence is a barrier to performing high-quality CPR ,
........ ro,.,
• Mock code simulation can increase nurses' self-confidence in
performing in a code
event (Herbersandl-leeoer,2016)
• Providing nurses with opportunities for practice is valuable to
improve self
confidence (MMonMal. , 2019)
"teunivenityatBuffalo 1,-.\1a.1.JY ... .,ll'r1~VM
• Design: Demographic Questions - Secondary analysis of data from
the results of the MCSES survey
• Four questions:
- CC and MS floors at a large urban hospital 1. How many years have
you been working as a nurse?
• Setting:
• Subjects and recruitment: 2. What gender do you identify
as?
- Convenience sample of 311 nurses employed in critical care and
med-surg 3. What unit do you currently work on?
- Inclusion criteria: 4 . Do you have past experience with mock
codes?
- a)18 years of age and older
- b) graduated from an accredited nursing school
- c) participated in the MCSES survey
Measurement Tool Sample Questions For the following questions,
please rate your confidence by choosing a designated number on a
scale from
• Mock Code Self-Efficacy Scale (MCSES) 0 to 10 with O being "No
Confidence~ and 10 being "Total Confidence~
• Variable: Nurses' self-efficacy 1.
Howconfidentareyouatassessingand identifying a patient in
respiratory failure? • Tool consists of 12 questions on clinical
skills
- Grouped in three subscales 2 3 4 5 6 7 8 9 10 NOTE: Adapted from
Oetker-Blackand Davis(2019)
• Shown to have reliability, face, and content validity No
Confidence Total Confidence
10. How confident are you at identifying which dysrhythmias would
require an unsynchronized shock (defibrillation)in cardiopulmonary
arrest?
V sual Analog sca le answers
• Scale from 0-10
• 0 = No confidence • 10 = Total Confidence No Confidence Total
Confidence
'(eun1ver.utyatBuffulo ,..,\1mi.n-\ltycl,..ll'Jlt
Total Sample Demographics
• 311 nurses surveyed
• Years of experience as a nurse ranged from 0-45 years
- 11. 75 the average number of years
• 267 (85.9%) females and 27 (8.7%) males
• 77 (24.8%) work on CC unit
• 146 (46.9%) work on MS unit
• 170 (58.2%) nurses that had PMCE
• 122 (41.8%) nurses did NOT have PCME
Total Sample Clinical Skill Comparison
• Three skills that had the lowest level of confidence:
1. Identify which dysrhythmias would require an unsynchronized
shock
(defibrillation) in cardiopulmonary arrest (M=6.72) (Question
#10)
2 . Name the first medication given to a client in cardiopulmonary
arrest
during a code blue situation (M=7.18) (Question #11)
3. Recognize pulseless ventricular tachycardia on the cardiac
monitor
(M=7.49). (Question #9)
10 h5a 1~1'ywi.khd)-.rh)1hlniu 'Mlllld~lllre •n
unsyndirur.iin-llmock Mcd•S.IQ.
lPmo.idc~~bCntmt.lCK-1:68 9,or,.1.,11 tdil:nl:ri ll•IIOQ) lrl
1cllffllwllh1pod:C'IIINU c•nlior,uJmoasy •ITHI
orn:M.l!ltl~birc M~IQ 129• l.119 l.299 I I NMM 1bonni1m,;dk:iiOOU
-4 lni1l_.11rchdl~ 1h-en1e>11ellen1in
onl!Optl.lmPNl)llltff'M i,.k,d.Sln lor1d~witbaul • p:it. dunn1 •
ooJc,blue1\w• rl011
Table 3
H.4ssocia1ion Anal)'5is of Uni/ Ve,,..., Past Mock Code Experience
(N~211) "' s;g Past Mock Code Experience
Yes No EkO RlCOSPJli(ln Cntkal Oln:! $1 i16,62 6..0IS To1aJ
MN-Swl UO 41,28 9.507 Critical Care 56 21 77 Unit CPRiwessmm1
Critic-lJC•n: 68 36,96 "366
Mcd-s»Ig 76 70 146 M«l-:i!Q 130 32.93 6.719
Actioosdllftllg CritkaJC&n:: 61 26.41 •.869 Toial 132 91 223
«wk 6.967 196 .000
Med- !Jf.l UO 19.60 7.NK
x2(1)=8.919, p=.003
~~;:::~WIina
Years of Experience vs Mock Code Experience ll! Sig
• Compared years of experience as a nurse to PMCE EKGreoogni1ioa
Yes 45.76 6.401
• Greater years experience; increased PMCE No 108• 38.77
11.041
36.26 4.382 000
No 109 11.60 1.990
" sinM:oricobsc:rvation
Lowest Confidence Scores of Skills by Unit Lowest Confidence Scores
of Skills by PMCE • Onlyoneskill , recognizingasystole,
wasnotstatisticallysignificant
=IMl1W•t1ff•±· ·
wouldrequ1reonunsynchromzedshock wouldrequireonunsynchronizedshock
(def1bnllat1on)incard1opulmonaryarrest cardiopulmonaryarrest
(M=S.16) (def1bnllat1on)incard1opulmonaryarrest
(defibrillaton)incardiopulmonaryarrest (M=783) (M=844)
(M=S.80)
91ventoacl1ent1ncard1opulmonaryarrest
toaclentincardiopulmonaryarrestduringa codebues1tuat1on(M=810)
bluesituation (M=S.99) dunngacodeblues1uat1 n(M=871)
codebluesituation(M=6.62)
• Question #9 Recognize pulsetess VT on the Question#9;
RecognizepulselessVTonthe • Quest1on#1 , ldent1fyandassessachentin
Question#9; RecognizepulselessVTonthe
card1acmomtoranduponassessmentofthe
cardiacmonitoranduponassessmentofthe
resp1ratoryfa1Iure(M=893) cardiacmonitoranduponassessmentofthe
chent(M=B 2) dient(M=6.19) client(M=G.82)
Strengths and Limitations
• Missing data on demographic tool • Statistically significant
outcomes
• Secondary data set analysis • Standardized measurement tool
• Project initiated by QI committee
Conclusions
• MS nurses overall had decreased confidence levels in skill
assessment and were less likely to have PMCE than CC nurses
• Nurses with PMCE were more confident in performing the clinical
skills
• Nurses with more years experience had increased PMCE
DNP essentials
and Systems Thinking
• DNP Essential Ill :
Practice
Recommendations for Future Training
• Mock codes should be performed routinely on MS units
• Optimization of ISMCs should include the clinical skills
identified has having lower levels of confidence
• Survey compliance
399.hm,-11dx'K'i w 1J0.4Q17/~irr2016?HJ
INA CSL Standards Comminee (2016). INA CSL standards ofb,,;t
pn,cticc, Simulation™ Simulation design_ Clinical Simulation in
Nursing, ll(S), SS-Sl2
"(e UnivenityatB ufblo 1 .... \ tN .._.,.,...,,yd "-' lOti
h•m·lldx.doi_o,gl] O JQ971go.i /ltllVY\ONWINVl;iQ4
QUESTIONS???
Evaluating Nurses’ Self-Efficacy related to In Situ Mock Code
Simulation Training
Acknowledgements
Abstract
The DNP Essentials
Needs Assessment to Identify Gaps in Practice with Mock Codes
Data Analysis
Table 2 Inferential Statistics by Unit
Table 3 Association Analysis
Table 5 Inferntial Statistics Past Mock Code
Appendix A UB IRB Approval Letter
Appendix B Mock Code Self-Efficacy Scale: Part A Demographics
Appendix C Mock Code Self-Efficacy Scale: Part B MCSES Tool
Appendix D Permission from author to use MCSES